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142 processing; ELEN E6762: Computer communication networks, II; ELEN E6717: Information theory; COMS E6181: Advanced internet services; ELEN E6950: Wireless and mobile networking, I; or ELEN E6001-E6002: Advanced projects in electrical engineering with an appropriate project. A cross-disciplinary project in areas related to new media technology is especially encouraged. Concentration in Lightwave (Photonics) Engineering Advisers: Prof. Keren Bergman, Prof. Paul Diament, Prof. Richard Osgood, Prof. Amiya Sen, Prof. Tony Heinz 1. Satisfy M.S. degree requirements. 2. Take both ELEN E4411: Fundamentals of photonics and ELEN E6403: Classical electromagnetic theory (or an equivalent, such as APPH E4300: Applied electrodynamics or PHYS G6092: Electromagnetic theory). 3. One more device/circuits/photonics course such as: ELEN E4401: Wave transmission and fiber optics; ELEN E6412: Lightwave devices; ELEN E6413: Lightwave systems; ELEN E4405: Classical nonlinear optics; ELEN E6414: Photonic integrated circuits; ELEN E4314: Communication circuits; ELEN E4501: Electromagnetic devices and energy conversion. 4. At least two approved courses in photonics or a related area. Concentration in Wireless and Mobile Communications Adviser: Prof. Gil Zussman 1. Satisfy M.S. degree requirements. 2. One basic circuits course such as: ELEN E4312: Analog electric circuits; ELEN E4314: Communication circuits; ELEN E6314: Advanced communication circuits; ELEN E6312: Advanced analog ICs. 3. Two communications or networking courses such as: CSEE W4119: Computer networks; ELEN E4702: Digital communications; ELEN E4703: Wireless communications; ELEN E6711: Stochastic signals and noise; ELEN E4810: Digital signal processing; ELEN E6950: Wireless and mobile networking, I; ELEN E6951: Wireless and mobile networking, II; ELEN E6761: Computer communication networks, I; ELEN E6712: Communication theory; ELEN E6713: Topics in communications; ELEN E6717: Information theory. 4. At least two approved courses in wireless communications or a related area. Concentration in Microelectronic Circuits Advisers: Prof. Yannis Tsividis, Prof. Charles Zukowski, Prof. Kenneth Shepard, Prof. Peter Kinget 1. Satisfy M.S. degree requirements. 2. One digital course: ELEN E4321: Digital VLSI circuits or ELEN E6321: Advanced digital electronic circuits. 3. One analog course such as: ELEN E4312: Analog electronic circuits; ELEN E4215: Analog filter synthesis and design; ELEN E6312: Advanced analog integrated circuits; ELEN E6316: Analog circuits and systems in VLSI; ELEN E4314: Communication circuits; ELEN E6314: Advanced communication circuits. 4. One additional course such as: ELEN E4332: VLSI design laboratory; ELEN E6211: Circuit theory; ELEN E6261: Computational methods of circuit analysis; ELEN E6304: Topics in electronic circuits; ELEN E6318: Microwave circuit design. 5. At least two additional approved courses in circuits or a related area. Concentration in Microelectronic Devices Advisers: Prof. Wen Wang, Prof. Richard Osgood, Prof. Ioannis (John) Kymissis 1. Satisfy M.S. degree requirements. 2. One basic course such as: ELEN E4301: Introduction to semiconductor devices or ELEN E4411: Fundamentals of photonics. 3. One advanced course such as: ELEN E4193: Modern display science and technology; ELEN E4944: Principles of device microfabrication; ELEN E4503: Sensors, actuators, and electromechanical systems; ELEN E6151: Surface physics and analysis of electronic materials; ELEN E6331: Principles of semiconductor physics, I; ELEN E6332: Principles of semiconductor physics, II; ELEN E6333: Semiconductor device physics; ELEN E6945: Nanoscale fabrication and devices. 4. At least two approved courses in devices or a related area. Concentration in Systems Biology Advisers: Prof. Dimitris Anastassiou, Prof. Pedrag Jelenkovic, Prof. Aurel Lazar, Prof. Kenneth Shepard, Prof. Xiaodong Wang, Prof. Charles Zukowski 1. Satisfy M.S. degree requirements. 2. Take both ECBM E4060: Introduction to genomic information science and technology and BMEB W4011: Computational neuroscience, I: circuits in the brain 3. Take at least one course from CBMF W4761: Computational genomics; CHBC W4510: Molecular systems biology, I; CHBC W4511: Molecular systems biology, II; BIST P8139: Theoretical genetic modeling (Biostatistics); ELEN E6010: Systems biology; EEBM E6020: Methods in computational neuroscience; BMEE E6030: Neural modeling and neuroengineering; APMA E4400: Introduction to biophysical modeling; CHEN E4700: Principles of genomic technologies; ELEN E4312: Analog electronic circuits. 4. Take at least one course from ELEN E608x: Topics in systems biology; ELEN E6717: Information theory; ELEN E6201: Linear systems theory; EEME E6601: Introduction to control theory; ELEN E6711: Stochastic models in information systems; ELEN E6860: Advanced digital signal processing; EEBM E6090: Topics in computational neuroscience and neuroengineering; ELEN E6261: Computational methods of circuit analysis. courses in electrical engineering ELEN E1101x or y The digital information age 3 pts. Lect: 3. Professor Vallancourt. An introduction to information transmission and storage, including technological issues. Binary numbers; elementary computer logic; digital speech and image coding; basics of compact disks, telephones, modems, faxes, UPC bar codes, and the World Wide Web. Projects include implementing simple digital logic systems and Web pages. Intended primarily for students outside the School of Engineering and Applied Science. The only prerequisite is a working engineering 2011–2012
knowledge of elementary algebra. ELEN E1201x and y Introduction to electrical engineering 3.5 pts. Lect: 3. Lab:1. Professor Vallancourt. Prerequisite: MATH V1101. Basic concepts of electrical engineering. Exploration of selected topics and their application. Electrical variables, circuit laws, nonlinear and linear elements, ideal and real sources, transducers, operational amplifiers in simple circuits, external behavior of diodes and transistors, first order RC and RL circuits. Digital representation of a signal, digital logic gates, flip-flops. A lab is an integral part of the course. Required of electrical engineering and computer engineering majors. ELEN E3043x Solid state, microwave and fiber optics laboratory 3 pts. Lect: 1. Lab: 6. Professor W. Wang. Prerequisites: ELEN E3106 and ELEN E3401. Optical electronics and communications. Microwave circuits. Physical electronics. ECBM E3060x Introduction to genomic information science and technology 3 pts. Lect: 3. Professor Anastassiou. Introduction to the information system paradigm of molecular biology. Representation, organization, structure, function and manipulation of the biomolecular sequences of nucleic acids and proteins. The role of enzymes and gene regulatory elements in natural biological functions as well as in biotechnology and genetic engineering. Recombination and other macromolecular processes viewed as mathematical operations with simulation and visualization using simple computer programming. This course shares lectures with ECBM E4060, but the work requirements differ somewhat. ELEN E3081x Circuit analysis laboratory 1 pt. Lab: 3. Professor Zukowski. Prerequisite: ELEN E1201 or equivalent. Corequisite: ELEN E3201. Companion lab course for ELEN E3201. Experiments cover such topics as: use of measurement instruments; HSPICE simulation; basic network theorems; linearization of nonlinear circuits using negative feedback; op-amp circuits; integrators; second order RLC circuits. The lab generally meets on alternate weeks. ELEN E3082y Digital systems laboratory 1 pt. Lab: 3. Professor Shepard. Corequisite: CSEE W3827. Recommended preparation: ELEN E1201 or equivalent. Companion lab course for CSEE W3827. Experiments cover such topics as logic gates; flip-flops; shift registers; counters; combinational logic circuits; sequential logic circuits; programmable logic devices. The lab generally meets on alternate weeks. ELEN E3083y Electronic circuits laboratory 1 pt. Lab: 3. Professor Vallancourt. Prerequisite: ELEN E3081. Corequisite: ELEN E3331. Companion lab course for ELEN E3331. Experiments cover such topics as macromodeling of nonidealities of opamps using SPICE; Schmitt triggers and astable multivibrations using opamps and diodes; logic inverters and amplifiers using bipolar junction transistors; logic inverters and ring oscillators using MOSFETs; filter design using op-amps. The lab generally meets on alternate weeks. ELEN E3084x Signals and systems laboratory 1 pt. Lab: 3. Professor X. Wang. Corequisite: ELEN E3801. Companion lab course for ELEN E3801. Experiments cover topics such as: introduction and use of MATLAB for numerical and symbolic calculations; linearity and time invariance; continuous-time convolution; Fourier-series expansion and signal reconstruction; impulse response and transfer function; forced response. The lab generally meets on alternate weeks. ELEN E3106x Solid-state devices and materials 3.5 pts. Lect: 3. Recit: 1. Professor Kymissis. Prerequisite: MATH V1201 or equivalent. Corequisite: PHYS C1403 or PHYS C2601 or equivalent. Crystal structure and energy band theory of solids. Carrier concentration and transport in semiconductors. P-n junction and junction transistors. Semiconductor surface and MOS transistors. Optical effects and optoelectronic devices. ELEN E3201x Circuit analysis 3.5 pts. Lect: 3. Recit: 1. Professor Zukowski. Prerequisite: ELEN E1201 or equivalent. Corequisite: MATH V1201. A course on analysis of linear and nonlinear circuits and their applications. Formulation of circuit equations. Network theorems. Transient response of first and second order circuits. Sinusoidal steady stateanalysis. Frequency response of linear circuits. Poles and zeros. Bode plots. Two-port networks. ELEN E3331y Electronic circuits 3 pts. Lect: 3. Professor Vallancourt. Prerequisites: ELEN E3201. Operational amplifier circuits. Diodes and diode circuits. MOS and bipolar junction transistors. Biasing techniques. Small-signal models. Single-stage transistor amplifiers. Analysis and design of CMOS logic gates. A/D and D/A converters. ELEN E3390y Electronic circuit design laboratory 3 pts. Lab: 6. Professor Vallancourt. Prerequisites: ELEN E3082, E3083, E3331, E3401, E3801. Advanced circuit design laboratory. Students work in teams to specify, design, implement and test an engineering prototype. The work involves technical as well as non-technical considerations, such as manufacturability, impact on the environment, and economics. The projects may change from year to year. ELEN E3399x Electrical engineering practice 1 pt. Professor Vallancourt. Design project planning, written and oral technical communication, practical aspects of engineering as a profession, such as career development and societal and environmental impact. Generally taken senior year. ELEN E3401y Electromagnetics 4 pts. Lect: 3. Professor Diament. Prerequisite: MATH V1201, PHYS C1402 or PHYS C1602, or equivalents. Basic field concepts. Interaction of time-varying electromagnetic fields. Field calculation of lumped circuit parameters. Transition from electrostatic to quasistatic and electromagnetic regimes. Transmission lines. Energy transfer, dissipation, and storage. Waveguides. Radiation. EEME E3601x Classical control systems 3 pts. Lect: 3. Professor Longman. Prerequisite: MATH E1210. Analysis and design of feedback control systems. Transfer functions; block diagrams; proportional, rate, and integral controllers; hardware; implementation. Routh stability criterion, root locus, Bode and Nyquist plots, compensation techniques. ELEN E3701y Introduction to communication systems 3 pts. Lect: 3. Professor Kalet. Prerequisite: ELEN E3801. Corequisite: IEOR E3658. A basic course in communication theory, stressing modern digital communication systems. Nyquist sampling, PAM and PCM/ DPCM systems, time division multipliexing, high frequency digital (ASK, OOK, FSK, PSK) systems, and AM and FM systems. An introduction to noise processes, detecting signals in the presence of noise, Shannon’s theorem on channel capacity, and elements of coding theory. ELEN E3801x Signals and systems 3.5 pts. Lect: 3. Professor X. Wang. Corequisite: MATH V1201. Modeling, description, and classification of signals and systems. Continuous-time systems. Time domain analysis, convolution. Frequency domain analysis, transfer functions. Fourier series. Fourier and Laplace transforms. Discrete-time systems and the Z transform. CSEE W3827x and y Fundamentals of computer systems 3 pts. Lect: 3. Professors Kim and Rubenstein. Prerequisites: An introductory programming course. Fundamentals of computer organization and digital logic. Boolean algebra, Karnaugh maps, basic gates and components, flipflops and latches, counters and state machines, basics of combinational and sequential digital design. Assembly language, instruction sets, ALUs, single-cycle and multi-cycle processor design, introduction to pipelined processors, caches, and virtual memory. 143 engineering 2011–2012
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Bulletin 2011 -2012
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Bulletin 2011 -2012
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a message from the dean As students
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About the School and University
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3 After receiving a master’s degr
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Resources and Facilities 5 A Colleg
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• CourseWorks is the University c
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Undergraduate Studies
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students improve their ability to e
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transistors, first order RC and RL
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possible overseas destinations and
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more than 68 transfer points toward
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Programs Registered with the New Yo
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Applicants may submit results of th
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Undergraduate Tuition, Fees, and Pa
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financial aid for undergraduate stu
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Graduate Studies
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statements covering these special r
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33 Completion of Requirements The r
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graduate admissions 35 Office of Gr
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Graduate tuition, fees, and payment
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financial aid for graduate study 39
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esearch assistantships, readerships
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Faculty and Administration
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45 Xi Chen Associate Professor of E
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S. G. Steven Kou Professor of Indus
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Tiffany Shaw Assistant Professor of
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Enders Robinson Maurice Ewing and J
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Departments and Academic Programs
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55 IEOR INAF INTA MATH MEBM Industr
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techniques based on the theory of g
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squares method, pseudo-inverses, si
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iomedical engineering 351 Engineeri
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of courses in mathematics, physics,
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iomedical engineering. Up to 12 poi
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BMEN E4420y Biomedical signal proce
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BMEN E6400x Analysis and quantifica
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chemical nature of things and provi
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and broad-ranging nature of the deg
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chemical engineering: Third and Fou
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principles, environmental sciences,
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systems are treated next (dominant
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MINOR IN Entrepreneurship and Innov
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Interdisciplinary Courses and Cours
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Courses in Other Divisions of the U
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EESC V1201y Environmental risks and
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process of critical listening, both
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to Riemann geometry. Motion of part
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Campus and Student Life
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Preprofessional Advising The Office
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three Greek councils: The Interfrat
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student services 211 university hou
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Upperclass and Graduate Students Ma
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Scholarships, Fellowships, Awards,
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Class of 1900 (1940) Gift of the Cl
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James M. and Elizabeth S. Li Endowe
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Max Yablick Memorial Scholarship (1
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Applied Physics Faculty Award Award
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228 Academic Procedures and Standar
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230 calendar day, not a 24-hour tim
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232 Academic standing Academic Hono
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236 • Understand what instructors
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238 Student Grievances, Academic Co
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240 C. Discrimination and sexual ha
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242 columbia university resource li
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244 Medical Services John Jay Hall,
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246 The Morningside Heights Area of
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248 Center for Career Education (CC
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250 See also payments fellowships,
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252 parents contributions to educat
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254 notes engineering 2011-2012
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